Solving Percentage Errors: Different Magnitudes for Positive & Negative

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The discussion focuses on the concept of asymmetric percentage errors when calculating areas, particularly when subtracting two circular areas to find the area of an annulus. It highlights that the magnitude of positive and negative errors can differ due to the nature of the calculations, as shown in examples involving square areas with varying side lengths. The conversation emphasizes that measurement errors can lead to non-symmetric uncertainties, especially when dealing with squared values, such as area. Participants clarify that while the errors are not inherently problematic, they result from how measurements are taken and analyzed. Understanding these differences is crucial for accurate calculations in various applications.
lavster
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How can you get positive and negative errors to be different in magnitude?

for example -

when calculating the error of the area of an annulus from two circular areas (ie subtracting one from the other, why is the positive error greater than the negative error

Thanks
 
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because the denominators are different...

like, say, you have $100 invested and you lose $20...that's a $20 loss...
Now you have $80...What percentage gain do you need to get your $20 back...
20/80 is 25%.

figures don't lie, but liars figure!
 
i understand the money analogy, but not when talking about the areas - sorry! :S we are only subtracting once
 
lavster said:
i understand the money analogy, but not when talking about the areas - sorry! :S we are only subtracting once

Could you illustrate by an example what you are concerned about?
 
Imagine a square where both sides are known with a precision of 10% - they might be 10% shorter or 10% longer, but not more. What is the maximal deviation?

Larger area: Both sides 10% longer, total area 1.1^2 = 1.21 of the original area (21% more).
Smaller area: Both sides 10% shorter, total area 0.9^2 = 0.81 of the original area (19% less).
Do you see the difference?
 
mfb said:
Imagine a square where both sides are known with a precision of 10% - they might be 10% shorter or 10% longer, but not more. What is the maximal deviation?

Larger area: Both sides 10% longer, total area 1.1^2 = 1.21 of the original area (21% more).
Smaller area: Both sides 10% shorter, total area 0.9^2 = 0.81 of the original area (19% less).
Do you see the difference?

I see the difference, but why do you see this as a problem?
 
The error depends on how the measurement was taken and what analysis was done. When you do math on the measurement, the errors will change shape. If you measure a circle's radius with a ruler with a symmetric error in the length, then the error in the area is not symmetric, because area goes as length squared.
 
mathman said:
I see the difference, but why do you see this as a problem?
Where did I say that it is a problem?
I just said that you can get asymmetric uncertainties in this way.
 
ah great :) thanks :)
 

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